(Read image) 6/25 The 1800-kg rear-wheel-drive car accelerates forward at a rate of g/2. If the modulus of each of therear and front springs is 35 kN/m, estimate the resulting momentary nose-up pitch angle 0. (This upwardpitch angle during acceleration is called squat, while the downward pitch angle during braking is calleddive!) Neglect the unsprung mass of the wheels and tires. (Hint: Begin by assuming a rigid vehicle.)Answer0 = 0.964°GE600 mmAB15001500mmmmPROBLEM 6/25

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Answered: 6/25 The 1800-kg rear-wheel-drive car…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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B r P F A UBC Engineering Your team is prototyping a simple braking system for your model car. The 3.4 kg wheel with a radius of r = rad 0.15 m is rotating at w = 18 - .A servo motor can apply a variable force F, which in its first two seconds of operation is equal to F = 10t N and afterwards is equivalent to a constant force of F = 20 N . If the coefficient of kinetic friction between the braking arm and the wheel is μ= 0.2, determine the time needed for the wheel to come to a full stop. The point of contact P between the wheel and the arm is a distance r = -0.2 + 0.26 ĵ m from point A. The force of the servo motor is applied at exactly half of the horizontal distance to A from the point of contact. Assume the wheel can be treated as a disk and that the braking arm is massless. t =
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A flywheel weights 592 kg with a diameter 1.4 m. The flywheel rotates at 979 revolution per minute (rpm). If a constant braking torque 522 N.m is applied to the shaft during the rotation, calculate the number of revolutions turned through before the flywheel is coming to a complete stop.
0:45] am- Google Chrome du/mod/quiz/attempt.php?attempt=2340155&cmid=742781 P 250 mm 400 mm Time left 0:28:25 A = The following figure shows a spool that has a mass of 130 kg and a radius of gyration kg 0.3 m. If the coefficients of static and kinetic friction at A are μ, 0.86 and 0.81, respectively, and if you know that P 25000N, determine the following: a) Draw free body diagram. b) the angular acceleration of the spool. c) the acceleration of the center of mass of the spool G. d) the normal force at point A. e) the friction force at A. = Q Search % 5 6 7 8 9 00
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1. A cart is being pulled by a motor. The cart has a mass of m = 200 kg. The motor applies a horizontal force of F = 800 N to the center of the right side of the cart. The cart is 1m tall, the total length is 1.5m, the wheels are 1m apart from each other, and the center of mass G is 0.4 m above the floor and on the horizontal center. Ignore friction. If there is no rotational movement of the cart, determine the following: 1. The cart's acceleration 2. The reaction (normal) force at the front pair of wheels. 3. The reaction (normal) force at the rear pair of wheels. F 77 TI T
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A solid sphere starts from rest at a height of 2.5 meters. rolls down a ramp without slipping, so no friction. The mass of the sphere is 2 kg. It The radius of the sphere is 0.02 m The moment of Inertia of a sphere is: I = (2/5)mr² ) Compute the change in gravitational potential energy when the ball rolls from the top to the bottom of the ramp. Use conservation of energy to compute the angular velocity, oo, in radians/s and the linear velocity in m/s at the end of the ramp. h1
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